Penetration Performance of the Train of Solid and Hollow Disks

Recent Advances in Solids/Structures and Application of Metallic Materials Pub Date : 1997-11-16 DOI:10.1115/imece1997-0524

M. Lee

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Abstract

The penetration performance of homogeneous disk (μ = 0) and thick walled disk (μ < 0.5) projectiles are investigated numerically for length-to-diameter ratio (L/D) of 1/8 and 1/4, where μ is the ratio of inner to outer diameter of a disk. Penetrations of tungsten alloy projectiles up to 4 successive solid disks (SD) and hollow disks (HD) with spacing of 1.5, 2 and 3 diameters into rolled homogeneous armor (RHA) at 2.6 km/s were simulated with a finite difference nonlinear wave propagation program. The most obvious results from the calculations are that even at 2.6 km/s the total penetration of a 4-segmented projectile can not be obtained simply be multiplying the depth of a single disk by four, especially for L/D = 1/8. Although HD may be more efficient, in terms of mass, than SD of equal outer diameter, it is observed that precursor or jet interacts with a train of spaced HD. This interaction significantly reduces the penetration performance, which was also measured in the long tubular projectiles. The degradation in total penetration becomes worse as μ increases. For HD of L/D = 1/4 case, the degradation in penetration becomes less since the effect of the interaction of jet with successive disks is relatively small.

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实心和空心圆盘串的穿透性能

对均匀盘(μ = 0)和厚壁盘(μ < 0.5)弹丸在长径比(L/D)为1/8和1/4时的侵彻性能进行了数值研究，其中μ为盘的内径与外径之比。采用有限差分非线性波传播程序，模拟了钨合金弹丸以2.6 km/s的速度连续4个直径分别为1.5、2和3倍直径的实心盘(SD)和空心盘(HD)穿透轧制均匀装甲(RHA)的过程。最明显的计算结果是，即使在2.6 km/s的速度下，四段弹丸的总侵深也不能简单地将单个圆盘的深度乘以4，特别是当L/D = 1/8时。虽然在质量方面，HD可能比相同外径的SD更有效，但可以观察到前驱体或射流与间隔的HD序列相互作用。这种相互作用显著降低了侵彻性能，这在长管弹中也得到了测量。随着μ的增大，总穿深的退化程度越来越严重。当HD = L/D = 1/4时，由于射流与连续圆盘相互作用的影响相对较小，穿透退化较小。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Recent Advances in Solids/Structures and Application of Metallic Materials

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